洋葱鳞茎薄壁细胞原生质体胞质肌动蛋白质微丝骨架的形态与结构

使用四甲基罗丹明标记的鬼笔环碱(TRITC-Ph)探针,以新分离的洋葱鳞茎薄壁细胞原生质体为材料,观察了细胞胞质肌动蛋白微丝骨架的结构与形态。研究结果发现洋葱鳞茎内部细胞的细胞质内存在极丰富而精细的肌动蛋白微丝束。这些肌动蛋白微丝束的直径约1.0—4.5μm,有下列四种不同的排列形式:(1)相互平行排列,方向大体与细胞的长轴垂直;(2)从一些结合位点辐射而出,并向四周延伸,然后再相互交织在一起,形成一个非常密集而复杂的网络;(3)细而稀疏,相互交织成网状,两端分别与质膜不同位置上的结合位点相连;(4)粗而稀疏,相互交织成网状,两端都与质膜相连,或一端与质膜相连,另一端与细胞核周围的微丝束网络相连。部分微丝束具有“Y”形分支。     

杜仲次生木质部导管分子分化中的程序性死亡

运用原位末端标记法,证明了杜仲（ＥｕｃｏｍｍｉａｕｌｍｏｉｄｅｓＯｌｉｖ．）次生木质部的导管分子分化过程是程序性死亡（ｐｒｏｇｒａｍｍｅｄｃｅｌｄｅａｔｈ,ＰＣＤ）过程。它包括一系列的物质合成和细胞结构的解体和自溶：细胞核逐步变得极不规则,染色质高度凝集,有些细胞核的核周腔膨大,核周腔内存在着包裹有核物质的内膜凸起,最后,核膜消失,核解体。细胞核是ＰＣＤ中最后消失的细胞器之一。线粒体有两种解体方式,一种为线粒体内部结构紊乱,嵴极不清晰,线粒体皱缩变形;另一种为线粒体出现一些电子密度低的透明区,进而裂开。内质网囊泡化,相邻的内质网槽库之间互相连接,形成分隔。内质网和液泡共同行使溶酶体功能,吞噬各种细胞器残体。解体后的物质可能有两种去向,一是通过纹孔运输到邻近的细胞中,二是转化成构建自身次生壁的物质     

紫萼花粉粒和花粉管中微丝的超微结构

用常规化学固定和化学固定前用鬼笔环肽处理两种电镜样品制作技术,分别研究了紫萼[Hosta venteicosa (=H.coerulea]成熟花粉粒和幼花粉管中的微丝的超微结构。结果表明,在常规电镜固定中花粉粒中的微丝能保存,但在花粉管中的则遭受破坏。用鬼笔环肽处理后化学固定的方法,微丝在花粉管中能良好地保存。在花粉粒中平行的微丝形成束,表现为具分布的特点,即限于分布在它们功能的区域,并且微丝束经常紧密地与营养核贴近。在幼花粉管中微丝束表现为在线粒体、质体、内质网、小泡和小液泡的表面通过,并常常与脂体紧密联结。这些现象表明在花粉萌发和花粉管生长时,微丝与营养核及与其它细胞器的运动之间存在某些联系的迹象。     

微丝的基本性质与细胞核肌动蛋白

微丝,作为细胞骨架的重要成员,普遍存在于所有的真核细胞中。构成微丝的肌动蛋白,与肌球蛋白一起作用,使细胞产生和传导机械力,并促进细胞运动。尽管人们很早就已经认识到体细胞核中存在单体肌动蛋白,但细胞核中聚合的微丝如何动态调控及行使何种功能,仍存在争议。该文概述了微丝细胞骨架的基本性质和成核过程,并讨论细胞核内肌动蛋白的功能。     

应用水稻花粉离体萌发体系观察花粉管内微丝分布

采用非固定、DMSO渗透和异硫氰酸标记的鬼笔环肽（FITC—Ph）染色方法,观察水稻花粉离体萌发过程中花粉管内肌动蛋白微丝的形态和分布。结果表明：（1）水稻花粉水合2min后即可萌发,花粉管生长速度在600～1500μm／h之间。（2）水合而未萌发的花粉粒中,大量较短的梭形微丝束构成微丝网络结构,萌发过程中花粉粒内的梭形微丝束松解,部分微丝转移至萌发的花粉管内沿花粉管纵轴呈束状结构;随着花粉管的伸长,微丝束主要分布在花粉管中前端,但在花粉管顶端区域始终未见明显的微丝束。（3）水合后不能正常萌发的花粉粒内肌动蛋白微丝呈弥散不规则分布,在相同萌发时间生长迟缓的花粉管中,微丝束较少,且主要位于花粉管近萌发孔的部位。表明微丝骨架的形态和分布影响水稻花粉管的萌发和生长。     

核钙信号

尽管核周隙与内质网的腔相通,核膜上存在钙信号分子的受体等事实表明,细胞核存在一套相对独立的钙信号机制。作为核钙的贮存库,核被是核钙信号的发源地。核被中钙离子的充盈状态影响着核孔复合体的构象,从而调节核质间物质交流。已有证据显示,核钙信号与胞质钙信号在基因转录中的作用有所区别。核钙信号在细胞凋亡中发挥重要作用,其中,钙蛋白酶起着较为关键的作用。核钙信号研究为完整理解钙信号的生理功能开辟了新视野。     

黄蝉和姜花生殖细胞内肌动蛋白微丝的定位

用荧光标记的鬼笔碱染色，对离体的黄蝉和姜花的生殖细胞内肌动蛋白微丝的分布进行了研究．结果证明两种植物的生殖细胞内部都存在一个微丝网络．黄蝉生殖细胞的比姜花的简单，微丝束较粗。但姜花生殖细胞的网络微丝束比黄蝉的更紧密地环绕着核。用免疫荧光技术在黄蝉生殖细胞的分裂前期和中期，可以观察到一些微丝束的存在，但在分裂后期和末期细胞内的肌动蛋白则变为颗粒状。     

银杏精子细胞生毛体及其它细胞器的超微结构

生毛体与嗜锇颗粒是银杏 (Ginkgobiloba)精子细胞中最具有标志性的结构。生毛体是细胞质内一直径为 3～ 4μm的圆球形结构 ,它由一个电子致密的核心和由此向周边发散出的辐射状中心粒组成 ,致密核心上具有微管结构的弱电子染色区域 ,并有微管从生毛体延伸到细胞质。嗜锇颗粒直径为 1 0～ 2 0μm,呈圆球状 ,位于生毛体和细胞核之间 ,其相对的另一侧存在纤维颗粒体。在精子细胞质内 ,特别是嗜锇颗粒和生毛体周围线粒体、质体、内质网、高尔基体等细胞器丰富。银杏精子细胞核较大 ,在细胞核内 ,核仁结构呈球形 ,电子染色致密的颗粒区在周围 ,而纤维组分则在圆球的中间。在核膜表面布满了分布不均匀的核孔复合体。     

黄蝉和姜花生殖细胞内肌动蛋白微丝的定位

用荧光标记的鬼笔碱染色,对离体的黄蝉和姜花的生殖细胞内肌动蛋白微丝的分布进行了研究,结果证明两种植物的生殖细胞内部都存在一个微丝网络,黄蝉生殖细胞的比姜花的简单,微丝束较粗。但姜花生殖细胞的网络微丝束比黄蝉的更紧密地环绕着核。用免疫荧光技术在黄蝉生殖细胞的分裂前期和中期,可以观察到一些微丝束的存在,但在分裂后期和末期细胞内的肌动蛋白则变为颗粒状。     

玉米叶片细脉原生韧皮部筛分子的分化和超微结构 : 原生质体的变化

玉米（ＺｅａｍａｙｓＬ．）叶片细脉原生韧皮部筛分子开始分化时,首先出现长的粗面内质网潴泡和增厚的细胞壁,随后在质体中出现其特征性的拟晶体内含物。随着分化的进行,长的粗面内质网潴泡转化为较短的形态,最后聚集成一些小的堆叠并失去其核糖体。细胞核发生退化,但常保持到成熟期的后期,此时的细胞核由双层核膜或某些部位仅由内核膜包被,内含电子致密的不定形染色质团块。随后双层核膜破裂而变得不连续。在细胞核开始退化时,核周腔局部膨大。有的膨大核周腔的外核膜破裂,并伴随邻近的部分细胞质解体。在核退化过程中,除内质网外,质体和线粒体的结构也发生变化,而核糖体、细胞质基质、液泡和高尔基体则解体消失。成熟原生韧皮部筛分子的原生质组分分布在细胞边缘,由质膜、线粒体、小的滑面内质网堆叠及具拟晶体的Ｐ型质体组成。随着邻近后生韧皮部筛分子分化的进行,成熟原生韧皮部筛分子的原生质组分逐渐退化,最后消失。     

Interactions between the Nucleus and Cytoplasmic Organelles during the Cell Cycle of Euglena gracilis in Synchronized Cultures III. Association between the Nucleus and Chloroplasts at an Early Stage in the Cell Cycle under Photoorganotrophic Conditions (Part II)

Three-dimensional models of chloroplasts before and during theirassociation with the nucleus in Euglena gracilis Z were constructedbased on serial sections of cells taken during an early phaseof the cell cycle in synchronized cultures under photoorganotrophiccondition. Before association, the cell contained two to threechloroplasts which were composed of elongated tubular bodiesextending in different directions toward the cell periphery.These tubular arms of chloroplasts were drawn toward the nucleus,and folded, with concurrent coalescence, into a single giantbody surrounding the nucleus. A DAPI-fluorescence photomicrographof a giant chloroplast revealed that the chloroplast-nucleoidswere in the form of a continuous strand lying throughout thechloroplast body, and that some protuberances from the nucleoidstrand were in especially close proximity to the nuclear periphery. A new mode of the chloroplast-nucleus connection was observed.The nucleus had conspicuous protrusions, whose distal ends wereconnected with the chloroplast. The outer membrane of the nuclearenvelope was continuous with the outer chloroplast membrane,and at some sites, an open space was formed between the innernuclear membrane and the inner chloroplast membrane. ¹ This work was reported at the 48th Annual Meeting of the BotanicalSociety of Japan, held in Kyoto, in October, 1983. For PartI see Ehara et al. (1984).     

Nuclear protein migration involves two steps: rapid binding at the nuclear envelope followed by slower translocation through nuclear pores

When injected into the cytoplasm of Vero cells, nucleoplasmin rapidly concentrates in a narrow layer around the nuclear envelope and then accumulates within the nucleus. Transport into the nucleus can be reversibly arrested at the perinuclear stage by metabolic inhibitors or by chilling. Nucleoplasmin-coated colloidal gold particles concentrate around the nuclear envelope of Vero cells or Xenopus oocytes, and by electron microscopy of oocytes appear to be associated with fibrils attached to nuclear pore complexes. Perinuclear accumulation is not observed for the nonmigrating nucleoplasmin core fragment or nonnuclear proteins. We propose two steps in nuclear migration of proteins: rapid binding around the nuclear envelope, possibly to pore-associated fibrils, followed by slower, energy-dependent translocation through nuclear pores.     

Nuclear centering in Spirogyra: force integration by microfilaments along microtubules

The contribution of microtubules and microfilaments to the cytomechanics of transverse nuclear centering were investigated in the charophycean green alga Spirogyracrassa (Zygnematales). Cytoplasmic strands of enhanced rigidity and fasciate appearance radiate from the rim of the lenticular nucleus through the vacuole, frequently split once or twice and are attached to the helical chloroplast bands in the peripheral cytoplasm. The nucleus is encased in tubulin and a web of F-actin. Bundles of microtubules, emerging from the nuclear rim, are organized into dividing fascicles within the strands and reach to the inner surface of the chloroplast envelope. Organelles are translocated in both directions along similarly arranged fascicles of microfilament bundles which extend from the nucleus to the peripheral actin cytoskeleton. Application of microtubule- and/or microfilament-depolymerizing drugs affected the position of the nucleus only slowly, but in distinct ways. The differential effects suggest that nuclear centering depends on the tensional integrity of the perinuclear scaffold, with microfilaments conveying tension along stabilized microtubules and the actin cytoskeleton integrating the translocation forces generated within the scaffold. Received: 9 December 1996 / Accepted: 29 April 1997     

Further Observations on the Fine Structure of Acanthamoeba palestinensis (Reich, 1933). The Golgi Complex,Microbodies, and Mitochondria1

The fine structure of the trophozoite of Acanthamoeba palestinensis with a special emphasis on the Golgi complex, microbodies, and mitochondria has been examined. Golgi complexes are distributed throughout the cytoplasm but are most abundant in the perinuclear region. Usually two Goigi complexes are found in the same plane on opposite sides of the nucleus. One of them appears to be in an intimate association with the nuclear membrane. The region of contact contains compact cisternae, vesicles of various sizes, as well as granular and amorphous electron-dense material. Structural changes in the nuclear envelope are also observed in this area. A structure consisting of a Golgi complex and electron-dense microtubule organizing center, comparable to the centrosphere of other Acanthamoeba species, has been observed. Microbodies, surrounded by a single unit membrane and containing a granular matrix and tubular inclusions, are scattered throughout the cytoplasm. These organelles, circular (～1 μm in diameter) or ovoidal (～1 μm in length and ～0.5 μm in width) in section, have often an irregular outline. These microbodies are probably the morphological equivalent of peroxisomes and glyoxysomes. Most mitochondria show a typical structure including tubular cristae and intracristal inclusions. Occasionally mitochondria with two apposed double membranes running through the midline are found. Such atypical cristae have never been reported in small amoebae before.     

拟南芥根原生韧皮部筛管分子的超微结构

运用高压冷冻替代方法固定处理材料,在透射电镜下观察了拟南芥（Arabidopsis thaliana L.)根原生韧皮部筛管分子在发育过程中的超微结构变化。结果表明：在筛管分子发育过程中,细胞核具有细胞程序死亡的典型特征,出现核膜内陷、核质聚集并边缘化,核膜破毁以及最后核消失,核膜在破毁前一直呈饱满状态,未出现核膜皱缩,核裂瓣和核周腔明显膨大等现象。在成熟筛管分子的细胞质内,具单层膜的淀粉状颗粒,这些淀粉状态颗粒常与线粒体在一起,可能为线粒体的产能活动提供基质,小液泡发生于内质网,未见大液泡的形成。     

Intranuclear Inclusions in the Ameboid Cells of Protostelium zonatum*

SYNOPSIS. Two morphologically distinct types of intranuclear inclusions are found in ameboid cells of the protostelid mycetozoan Protostelium zonatum. One type of inclusion is a coiled tubular structure which in cross section appears as cisternae and oval to elliptical vesicles 40–60 nm in diameter. These tubular and vesicular structures are formed by a unit membrane that is connected directly with the inner nuclear membrane. The other type of inclusion is a membrane-bound structure that contains amorphous and/or fibrous material. These inclusions usually are present at several locations in a nucleus. No similar structures occur in the cytoplasm.     

ELECTRON MICROSCOPY OF THE VOLVOCACEAE AND ASTREPHOMENACEAE

Lang, Norma J. (U. Texas, Austin.) Electron microscopy of the Volvocaceae and Astrephomenaceae. Amer. Jour. Bot. 50(3): 280-300. Illus. 1963.—Clonal cultures of Gonium sociale, G. pectorale, Pandorina morum, Eudorina elegans, Eudorina sp., Volvulina steinii, V. pringsheimii, Platydorina caudata, Pleodorina illinoisensis, P. californica, Volvox aureus, V. tertius, V. globator, V. barberi, and Astrephomene gubernaculifera representing the Volvocaceae and Astrephomenaceae in the Volvocales were examined with the electron microscope and their ultrastructure compared. The ultrastructure of the various organelles is basically similar in the species studied and no increase in cellular complexity is found to accompany the evolutionary trends evidenced in the Volvocaceae. The ultrastructure of a colonial cell is basically that of Chlamydotnonas. A cytoplasmic membrane having a unit membrane structure encompasses a cell and is continuous with the double-membraned flagellar sheaths. The flagella contain the typical 9 + 2 fibril arrangement with the 2 axial fibrils terminating in a cylinder at the flagellar base and the 9 peripheral pairs continuing into the cytoplasm as a basal body. The organelles comprising the cytoplasm are: mitochondria with plate-like cristae; dictyosomes composed of stacks of agranular cisternae; small, rough or smooth-surfaced vesicles; an endoplasmic reticulum of granule-bearing and agranular tubules, lamellae and broad cisternae; vacuoles which are either contractile, contain fine granular and fibrillar material, or have dense contents probably representing polyphosphate; lipid bodies; and dense granules 100–150 A which have been called ribosomes. The finely granular nucleoplasm is surrounded by a porous, double-membraned nuclear envelope and contains a centric nucleolus composed of dense, spherical granules. The outer membrane of the nuclear envelope bears granules and may have granular extensions into the perinuclear cytoplasm. Each extension appears to encompass one or several dictyosomes and has been termed an “amplexus.” The amplexi are agranular on the surface contiguous to a dictyosome. A double-membraned chloroplast envelope is continuous around the single, cup-shaped chloroplast. The basic chloroplast units are discs closed at each end, occurring in stacks of varying number parallel to the envelope. The presumed proteinaceous matrix of the basal pyrenoid is penetrated by elongated, tubular elements which connect with the lamellar discs. Multiple rows of granules, associated with individual discs, form the anterior stigma within the chloroplast envelope. The colonial matrix is not a structureless, mucilaginous material uniting the cells in colonies, but it has rather a highly complex structure especially around the periphery of the colony and the flagellar channels. The apparent substitution of a fibrillar layer of the colonial matrix for the discrete compact cell wall, such as is found in Chlamydomonas, implies a greater degree of complexity in the evolution of these colonial genera than is generally assumed.     

An argyrophil fibrillar system and amitotic nuclear division in pars intermedia cells of the rainbow trout (Salmo irideus)

Summary Argyrophil fibrils were revealed in pars intermedia chromophobe cells of Salmo irideus. For the light microscopical demonstration of the fibrils a recently developed copper sulphate-silver protein technique for Bouin-fixed hypophyses was used.The fibrils, apparently belonging to one fibrillar system, are found only in limited regions of the cytoplasm. They occur in ring-, loop-, or cracknel shapes in the close vicinity of the rounded nucleus in the chromophobe cell, and continue in linear shape into the cell base or cell apex where they may end near the adjacent basement membrane.Electron microscopically, the fibrils are composed of filaments, 70–90 Å in diameter, which are arranged in parallel. Bundles of filaments are frequently found near the nucleus. In addition to perinuclear filaments, bundles of filaments with tiny offshoots occur in different areas of the cytoplasm, extending sometimes as far as the cell membrane which is located near the basement membrane of the pars intermedia epithelium.In cells with a bi- or trilobular, apparently amitotically dividing, nucleus a fibrillar loop or ring usually surrounds the interlobular part(s) of the nucleus. This relation of the fibrils to the dividing nucleus and their consisting of regularly arranged filaments indicates the significance of the fibrillar system in the chromophobe cell. It is thus suggested that the fibrillar system is involved in the constriction of the nucleus during amitosis.The number of chromophobe cells in which fibrils are light microscopically visible varied greatly among the rainbow trout used.Miss M. C. Wentzel is thanked for her technical assistance, Mr. M. Veenhuis for his advice and excellent help with the preparation of the electron micrographs, and Mr. L. Hoekstra for preparing the final drawings. Mr. N. J. Williams' corrections to the English are gratefully acknowledged.     

Electron microscopic characterization of nuclear egress in the sea urchin gastrula

Nuclear egress, also referred to as nuclear envelope (NE) budding, is a process of transport in which vesicles containing molecular complexes or viral particles leave the nucleus through budding from the inner nuclear membrane (INM) to enter the perinuclear space. Following this event, the perinuclear vesicles (PNVs) fuse with the outer nuclear membrane (ONM), where they release their contents into the cytoplasm. Nuclear egress is thought to participate in many functions such as viral replication, cellular differentiation, and synaptic development. The molecular basis for nuclear egress is now beginning to be elucidated. Here, we observe in the sea urchin gastrula, using serial section transmission electron microscopy, strikingly abundant PNVs containing as yet unidentified granules that resemble the ribonucleoprotein complexes (RNPs) previously observed in similar types of PNVs. Some PNVs were observed in the process of fusion with the ONM where they appeared to release their contents into the cytoplasm. These vesicles were abundantly observed in all three presumptive germ layers. These findings indicate that nuclear egress is likely to be an important mechanism for nucleocytoplasmic transfer during sea urchin development. The sea urchin may be a useful model to characterize further and gain a better understanding of the process of nuclear egress.